/* * Portions Copyright (C) 2003 Sun Microsystems, Inc. * All rights reserved. */ /* * * COPYRIGHT NVIDIA CORPORATION 2003. ALL RIGHTS RESERVED. * BY ACCESSING OR USING THIS SOFTWARE, YOU AGREE TO: * * 1) ACKNOWLEDGE NVIDIA'S EXCLUSIVE OWNERSHIP OF ALL RIGHTS * IN AND TO THE SOFTWARE; * * 2) NOT MAKE OR DISTRIBUTE COPIES OF THE SOFTWARE WITHOUT * INCLUDING THIS NOTICE AND AGREEMENT; * * 3) ACKNOWLEDGE THAT TO THE MAXIMUM EXTENT PERMITTED BY * APPLICABLE LAW, THIS SOFTWARE IS PROVIDED *AS IS* AND * THAT NVIDIA AND ITS SUPPLIERS DISCLAIM ALL WARRANTIES, * EITHER EXPRESS OR IMPLIED, INCLUDING, BUT NOT LIMITED * TO, IMPLIED WARRANTIES OF MERCHANTABILITY AND FITNESS * FOR A PARTICULAR PURPOSE. * * IN NO EVENT SHALL NVIDIA OR ITS SUPPLIERS BE LIABLE FOR ANY * SPECIAL, INCIDENTAL, INDIRECT, OR CONSEQUENTIAL DAMAGES * WHATSOEVER (INCLUDING, WITHOUT LIMITATION, DAMAGES FOR LOSS * OF BUSINESS PROFITS, BUSINESS INTERRUPTION, LOSS OF BUSINESS * INFORMATION, OR ANY OTHER PECUNIARY LOSS), INCLUDING ATTORNEYS' * FEES, RELATING TO THE USE OF OR INABILITY TO USE THIS SOFTWARE, * EVEN IF NVIDIA HAS BEEN ADVISED OF THE POSSIBILITY OF SUCH DAMAGES. * */ package demos.vertexArrayRange; import java.awt.*; import java.awt.event.*; import java.nio.*; import java.util.*; import javax.swing.*; import javax.media.opengl.*; import javax.media.opengl.glu.*; import com.sun.opengl.util.*; import com.sun.opengl.util.*; import demos.common.*; import demos.util.*; /**
A port of NVidia's [tm] Vertex Array Range demonstration to OpenGL[tm] for Java[tm] and the Java programming language. The current web site for the demo (which does not appear to contain the original C++ source code for this demo) is here.
This demonstration requires the following:
This demonstration illustrates the effective use of the java.nio direct buffer classes in JDK 1.4 to access memory outside of the Java garbage-collected heap, in particular that returned from the NVidia-specific routine wglAllocateMemoryNV. This memory region is used in conjunction with glVertexArrayRangeNV.
On a 750 MHz PIII with an SDRAM memory bus and a GeForce 256 running the Java HotSpot[tm] Client VM and OpenGL for Java 2.8, this demonstration attains 90% of the speed of the compiled C++ code, with a frame rate of 27 FPS, compared to 30 FPS for the C++ version. On higher-end hardware (a dual 667 MHz PIII with RDRAM and a GeForce 2) the demo currently attains between 65% and 75% of C++ speed with the HotSpot Client and Server compilers, respectively.
*/ public class VertexArrayRange extends Demo { public static void main(String[] args) { boolean startSlow = false; if (args.length > 1) { usage(); } if (args.length == 1) { if (args[0].equals("-slow")) { startSlow = true; } else { usage(); } } GLCanvas canvas = new GLCanvas(); VertexArrayRange demo = new VertexArrayRange(); if (startSlow) { demo.setFlag('v', false); // VAR off } canvas.addGLEventListener(demo); final Animator animator = new Animator(canvas); animator.setRunAsFastAsPossible(true); demo.setDemoListener(new DemoListener() { public void shutdownDemo() { runExit(animator); } public void repaint() {} }); Frame frame = new Frame("Very Simple NV_vertex_array_range demo"); frame.addWindowListener(new WindowAdapter() { public void windowClosing(WindowEvent e) { runExit(animator); } }); frame.setLayout(new BorderLayout()); canvas.setSize(800, 800); frame.add(canvas, BorderLayout.CENTER); frame.pack(); frame.show(); canvas.requestFocus(); animator.start(); } private static void usage() { System.out.println("usage: java VertexArrayRange [-slow]"); System.out.println("-slow flag starts up using data in the Java heap"); System.exit(0); } public VertexArrayRange() { setFlag(' ', true); // animation on setFlag('i', true); // infinite viewer and light setFlag('v', true); // VAR on } //---------------------------------------------------------------------- // Internals only below this point // private GLU glu = new GLU(); private boolean[] b = new boolean[256]; private static final int SIZEOF_FLOAT = 4; private static final int STRIP_SIZE = 48; private int tileSize = 9 * STRIP_SIZE; private int numBuffers = 4; private int bufferLength = 1000000; private int bufferSize = bufferLength * SIZEOF_FLOAT; private static final int SIN_ARRAY_SIZE = 1024; private FloatBuffer bigArrayVar; private FloatBuffer bigArraySystem; private FloatBuffer bigArray; private IntBuffer[] elements; private float[] xyArray; static class VarBuffer { public FloatBuffer vertices; public FloatBuffer normals; public int fence; } private VarBuffer[] buffers; private float[] sinArray; private float[] cosArray; // Primitive: GL_QUAD_STRIP, GL_LINE_STRIP, or GL_POINTS private int primitive = GL.GL_QUAD_STRIP; // Animation parameters private float hicoef = .06f; private float locoef = .10f; private float hifreq = 6.1f; private float lofreq = 2.5f; private float phaseRate = .02f; private float phase2Rate = -0.12f; private float phase = 0; private float phase2 = 0; // Temporaries for computation float[] ysinlo = new float[STRIP_SIZE]; float[] ycoslo = new float[STRIP_SIZE]; float[] ysinhi = new float[STRIP_SIZE]; float[] ycoshi = new float[STRIP_SIZE]; // For thread-safety when dealing with keypresses private volatile boolean toggleVAR = false; private volatile boolean toggleLighting = false; private volatile boolean toggleLightingModel = false; private volatile boolean recomputeElements = false; // Frames-per-second computation private boolean firstProfiledFrame; private int profiledFrameCount; private int numDrawElementsCalls; private long startTimeMillis; static class PeriodicIterator { public PeriodicIterator(int arraySize, float period, float initialOffset, float delta) { float arrayDelta = arraySize * (delta / period); // floating-point steps-per-increment increment = (int)(arrayDelta * (1<<16)); // fixed-point steps-per-increment float offset = arraySize * (initialOffset / period); // floating-point initial index initOffset = (int)(offset * (1<<16)); // fixed-point initial index arraySizeMask = 0; int i = 20; // array should be reasonably sized... while((arraySize & (1<> 16) & arraySizeMask; } public void incr() { index += increment; } public void decr() { index -= increment; } public void reset() { index = initOffset; } private int arraySizeMask; // fraction bits == 16 private int increment; private int initOffset; private int index; } private void setFlag(char key, boolean val) { b[((int) key) & 0xFF] = val; } private boolean getFlag(char key) { return b[((int) key) & 0xFF]; } private void ensurePresent(GL gl, String function) { if (!gl.isFunctionAvailable(function)) { final String message = "OpenGL routine \"" + function + "\" not available"; new Thread(new Runnable() { public void run() { JOptionPane.showMessageDialog(null, message, "Unavailable extension", JOptionPane.ERROR_MESSAGE); shutdownDemo(); } }).start(); throw new RuntimeException(message); } } public void init(GLAutoDrawable drawable) { // drawable.setGL(new TraceGL(drawable.getGL(), System.err)); // drawable.setGL(new DebugGL(drawable.getGL())); GL gl = drawable.getGL(); // Try and disable synch-to-retrace for fastest framerate gl.setSwapInterval(0); try { ensurePresent(gl, "glVertexArrayRangeNV"); ensurePresent(gl, "glGenFencesNV"); ensurePresent(gl, "glSetFenceNV"); ensurePresent(gl, "glTestFenceNV"); ensurePresent(gl, "glFinishFenceNV"); ensurePresent(gl, "glAllocateMemoryNV"); } catch (RuntimeException e) { shutdownDemo(); throw (e); } gl.glEnable(GL.GL_DEPTH_TEST); gl.glClearColor(0, 0, 0, 0); gl.glEnable(GL.GL_LIGHT0); gl.glEnable(GL.GL_LIGHTING); gl.glEnable(GL.GL_NORMALIZE); gl.glMaterialfv(GL.GL_FRONT_AND_BACK, GL.GL_AMBIENT, new float[] {.1f, .1f, 0, 1}, 0); gl.glMaterialfv(GL.GL_FRONT_AND_BACK, GL.GL_DIFFUSE, new float[] {.6f, .6f, .1f, 1}, 0); gl.glMaterialfv(GL.GL_FRONT_AND_BACK, GL.GL_SPECULAR, new float[] { 1, 1, .75f, 1}, 0); gl.glMaterialf(GL.GL_FRONT_AND_BACK, GL.GL_SHININESS, 128.f); gl.glLightfv(GL.GL_LIGHT0, GL.GL_POSITION, new float[] { .5f, 0, .5f, 0}, 0); gl.glLightModeli(GL.GL_LIGHT_MODEL_LOCAL_VIEWER, 0); // NOTE: it looks like GLUT (or something else) sets up the // projection matrix in the C version of this demo. gl.glMatrixMode(GL.GL_PROJECTION); gl.glLoadIdentity(); glu.gluPerspective(60, 1.0, 0.1, 100); gl.glMatrixMode(GL.GL_MODELVIEW); allocateBigArray(gl, true); allocateBuffersAndFences(gl); sinArray = new float[SIN_ARRAY_SIZE]; cosArray = new float[SIN_ARRAY_SIZE]; for (int i = 0; i < SIN_ARRAY_SIZE; i++) { double step = i * 2 * Math.PI / SIN_ARRAY_SIZE; sinArray[i] = (float) Math.sin(step); cosArray[i] = (float) Math.cos(step); } if (getFlag('v')) { gl.glEnableClientState(GL.GL_VERTEX_ARRAY_RANGE_NV); gl.glVertexArrayRangeNV(bufferSize, bigArrayVar); bigArray = bigArrayVar; } else { bigArray = bigArraySystem; } setupBuffers(); gl.glEnableClientState(GL.GL_VERTEX_ARRAY); gl.glEnableClientState(GL.GL_NORMAL_ARRAY); computeElements(); drawable.addKeyListener(new KeyAdapter() { public void keyTyped(KeyEvent e) { dispatchKey(e.getKeyChar()); } }); } private void allocateBuffersAndFences(GL gl) { buffers = new VarBuffer[numBuffers]; int[] fences = new int[1]; for (int i = 0; i < numBuffers; i++) { buffers[i] = new VarBuffer(); gl.glGenFencesNV(1, fences, 0); buffers[i].fence = fences[0]; } } private void setupBuffers() { int sliceSize = bufferLength / numBuffers; for (int i = 0; i < numBuffers; i++) { int startIndex = i * sliceSize; buffers[i].vertices = sliceBuffer(bigArray, startIndex, sliceSize); buffers[i].normals = sliceBuffer(buffers[i].vertices, 3, buffers[i].vertices.limit() - 3); } } private void dispatchKey(char k) { setFlag(k, !getFlag(k)); // Quit on escape or 'q' if ((k == (char) 27) || (k == 'q')) { shutdownDemo(); return; } if (k == 'r') { if (getFlag(k)) { profiledFrameCount = 0; numDrawElementsCalls = 0; firstProfiledFrame = true; } } if (k == 'w') { if (getFlag(k)) { primitive = GL.GL_LINE_STRIP; } else { primitive = GL.GL_QUAD_STRIP; } } if (k == 'p') { if (getFlag(k)) { primitive = GL.GL_POINTS; } else { primitive = GL.GL_QUAD_STRIP; } } if (k == 'v') { toggleVAR = true; } if (k == 'd') { toggleLighting = true; } if (k == 'i') { toggleLightingModel = true; } if('h'==k) hicoef += .005; if('H'==k) hicoef -= .005; if('l'==k) locoef += .005; if('L'==k) locoef -= .005; if('1'==k) lofreq += .1f; if('2'==k) lofreq -= .1f; if('3'==k) hifreq += .1f; if('4'==k) hifreq -= .1f; if('5'==k) phaseRate += .01f; if('6'==k) phaseRate -= .01f; if('7'==k) phase2Rate += .01f; if('8'==k) phase2Rate -= .01f; if('t'==k) { if(tileSize < 864) { tileSize += STRIP_SIZE; recomputeElements = true; System.err.println("tileSize = " + tileSize); } } if('T'==k) { if(tileSize > STRIP_SIZE) { tileSize -= STRIP_SIZE; recomputeElements = true; System.err.println("tileSize = " + tileSize); } } } public void display(GLAutoDrawable drawable) { GL gl = drawable.getGL(); // Check to see whether to animate if (getFlag(' ')) { phase += phaseRate; phase2 += phase2Rate; if (phase > (float) (20 * Math.PI)) { phase = 0; } if (phase2 < (float) (-20 * Math.PI)) { phase2 = 0; } } PeriodicIterator loX = new PeriodicIterator(SIN_ARRAY_SIZE, (float) (2 * Math.PI), phase, (float) ((1.f/tileSize)*lofreq*Math.PI)); PeriodicIterator loY = new PeriodicIterator(loX); PeriodicIterator hiX = new PeriodicIterator(SIN_ARRAY_SIZE, (float) (2 * Math.PI), phase2, (float) ((1.f/tileSize)*hifreq*Math.PI)); PeriodicIterator hiY = new PeriodicIterator(hiX); if (toggleVAR) { if (getFlag('v')) { gl.glEnableClientState(GL.GL_VERTEX_ARRAY_RANGE_NV); gl.glVertexArrayRangeNV(bufferSize, bigArrayVar); bigArray = bigArrayVar; } else { gl.glDisableClientState(GL.GL_VERTEX_ARRAY_RANGE_NV); bigArray = bigArraySystem; } toggleVAR = false; setupBuffers(); } if (toggleLighting) { if (getFlag('d')) { gl.glDisable(GL.GL_LIGHTING); } else { gl.glEnable(GL.GL_LIGHTING); } toggleLighting = false; } if (toggleLightingModel) { if(getFlag('i')) { // infinite light gl.glLightfv(GL.GL_LIGHT0, GL.GL_POSITION, new float[] { .5f, 0, .5f, 0 }, 0); gl.glLightModeli(GL.GL_LIGHT_MODEL_LOCAL_VIEWER, 0); } else { gl.glLightfv(GL.GL_LIGHT0, GL.GL_POSITION, new float[] { .5f, 0, -.5f, 1 }, 0); gl.glLightModeli(GL.GL_LIGHT_MODEL_LOCAL_VIEWER, 1); } toggleLightingModel = false; } if (recomputeElements) { computeElements(); recomputeElements = false; } gl.glClear(GL.GL_COLOR_BUFFER_BIT | GL.GL_DEPTH_BUFFER_BIT); gl.glPushMatrix(); final float[] modelViewMatrix = new float[] { 1, 0, 0, 0, 0, 1, 0, 0, 0, 0, 1, 0, 0, 0, -1, 1 }; gl.glLoadMatrixf(modelViewMatrix, 0); // FIXME: add mouse interaction // camera.apply_inverse_transform(); // object.apply_transform(); int cur = 0; int numSlabs = tileSize / STRIP_SIZE; for(int slab = numSlabs; --slab>=0; ) { cur = slab % numBuffers; if (slab >= numBuffers) { if (!gl.glTestFenceNV(buffers[cur].fence)) { gl.glFinishFenceNV(buffers[cur].fence); } } FloatBuffer v = buffers[cur].vertices; int vertexIndex = 0; gl.glVertexPointer(3, GL.GL_FLOAT, 6 * SIZEOF_FLOAT, v); gl.glNormalPointer(GL.GL_FLOAT, 6 * SIZEOF_FLOAT, buffers[cur].normals); for(int jj=STRIP_SIZE; --jj>=0; ) { ysinlo[jj] = sinArray[loY.getIndex()]; ycoslo[jj] = cosArray[loY.getIndex()]; loY.incr(); ysinhi[jj] = sinArray[hiY.getIndex()]; ycoshi[jj] = cosArray[hiY.getIndex()]; hiY.incr(); } loY.decr(); hiY.decr(); for(int i = tileSize; --i>=0; ) { float x = xyArray[i]; int loXIndex = loX.getIndex(); int hiXIndex = hiX.getIndex(); int jOffset = (STRIP_SIZE-1)*slab; float nx = locoef * -cosArray[loXIndex] + hicoef * -cosArray[hiXIndex]; // Help the HotSpot Client Compiler by hoisting loop // invariant variables into locals. Note that this may be // good practice for innermost loops anyway since under // the new memory model operations like accidental // synchronization may force any compiler to reload these // fields from memory, destroying their ability to // optimize. float locoef_tmp = locoef; float hicoef_tmp = hicoef; float[] ysinlo_tmp = ysinlo; float[] ysinhi_tmp = ysinhi; float[] ycoslo_tmp = ycoslo; float[] ycoshi_tmp = ycoshi; float[] sinArray_tmp = sinArray; float[] xyArray_tmp = xyArray; for(int j = STRIP_SIZE; --j>=0; ) { float y; y = xyArray_tmp[j + jOffset]; float ny; v.put(vertexIndex, x); v.put(vertexIndex + 1, y); v.put(vertexIndex + 2, (locoef_tmp * (sinArray_tmp[loXIndex] + ysinlo_tmp[j]) + hicoef_tmp * (sinArray_tmp[hiXIndex] + ysinhi_tmp[j]))); v.put(vertexIndex + 3, nx); ny = locoef_tmp * -ycoslo_tmp[j] + hicoef_tmp * -ycoshi_tmp[j]; v.put(vertexIndex + 4, ny); v.put(vertexIndex + 5, .15f); //.15f * (1.f - sqrt(nx * nx + ny * ny)); vertexIndex += 6; } loX.incr(); hiX.incr(); } loX.reset(); hiX.reset(); for (int i = 0; i < elements.length; i++) { ++numDrawElementsCalls; gl.glDrawElements(primitive, elements[i].capacity(), GL.GL_UNSIGNED_INT, elements[i]); if(getFlag('f')) { gl.glFlush(); } } gl.glSetFenceNV(buffers[cur].fence, GL.GL_ALL_COMPLETED_NV); } gl.glPopMatrix(); gl.glFinishFenceNV(buffers[cur].fence); if (getFlag('r')) { if (!firstProfiledFrame) { if (++profiledFrameCount == 30) { long endTimeMillis = System.currentTimeMillis(); double secs = (endTimeMillis - startTimeMillis) / 1000.0; double fps = 30.0 / secs; double ppf = tileSize * tileSize * 2; double mpps = ppf * fps / 1000000.0; System.err.println("fps: " + fps + " polys/frame: " + ppf + " million polys/sec: " + mpps + " DrawElements calls/frame: " + (numDrawElementsCalls / 30)); profiledFrameCount = 0; numDrawElementsCalls = 0; startTimeMillis = System.currentTimeMillis(); } } else { startTimeMillis = System.currentTimeMillis(); firstProfiledFrame = false; } } } public void reshape(GLAutoDrawable drawable, int x, int y, int width, int height) {} // Unused routines public void displayChanged(GLAutoDrawable drawable, boolean modeChanged, boolean deviceChanged) {} private void allocateBigArray(GL gl, boolean tryAgain) { float priority = .5f; bigArraySystem = setupBuffer(ByteBuffer.allocateDirect(bufferSize)); float megabytes = (bufferSize / 1000000.f); try { bigArrayVar = setupBuffer(gl.glAllocateMemoryNV(bufferSize, 0, 0, priority)); } catch (OutOfMemoryError e1) { // Try a higher priority try { bigArrayVar = setupBuffer(gl.glAllocateMemoryNV(bufferSize, 0, 0, 1.f)); } catch (OutOfMemoryError e2) { if (!tryAgain) { throw new RuntimeException("Unable to allocate " + megabytes + " megabytes of fast memory. Giving up."); } System.err.println("Unable to allocate " + megabytes + " megabytes of fast memory. Trying less."); bufferSize /= 2; numBuffers /= 2; allocateBigArray(gl, false); return; } } System.err.println("Allocated " + megabytes + " megabytes of fast memory"); } private FloatBuffer setupBuffer(ByteBuffer buf) { buf.order(ByteOrder.nativeOrder()); return buf.asFloatBuffer(); } private FloatBuffer sliceBuffer(FloatBuffer array, int sliceStartIndex, int sliceLength) { array.position(sliceStartIndex); FloatBuffer ret = array.slice(); array.position(0); ret.limit(sliceLength); return ret; } private void computeElements() { xyArray = new float[tileSize]; for (int i = 0; i < tileSize; i++) { xyArray[i] = i / (tileSize - 1.0f) - 0.5f; } elements = new IntBuffer[tileSize - 1]; for (int i = 0; i < tileSize - 1; i++) { elements[i] = IntBuffer.allocate(2 * STRIP_SIZE); for (int j = 0; j < 2 * STRIP_SIZE; j += 2) { elements[i].put(j, i * STRIP_SIZE + (j / 2)); elements[i].put(j+1, (i + 1) * STRIP_SIZE + (j / 2)); } } } private static void runExit(final Animator animator) { // Note: calling System.exit() synchronously inside the draw, // reshape or init callbacks can lead to deadlocks on certain // platforms (in particular, X11) because the JAWT's locking // routines cause a global AWT lock to be grabbed. Run the // exit routine in another thread. new Thread(new Runnable() { public void run() { animator.stop(); System.exit(0); } }).start(); } }